EP2116455A1 - Floor element in white and floor element and method for producing a floor element for a vehicle, such as a heavy goods vehicle, semi-trailer or trailer - Google Patents

Abstract

The element (BR) has cross webs (7, 7a, 8, 8a) aligned transverse to a longitudinal direction (L) of a floor element and dividing an area present between upper and lower covering layers into chambers (18). Covering elements (19, 20) are designed as hollow sections and have a longitudinal channel (21) that runs in a longitudinal direction of the section. The channel is connected with one of the chambers by access openings (24) and has a connection opening (26) for supplying a pourable foam e.g. polyurethane foam, where the openings discharge gases contained in the chambers. An independent claim is also included for a method for manufacturing a floor element for a vehicle.

Description

The invention relates to a Bodenrohelement, a floor element and a method for producing such a floor element for a vehicle, such as a truck, semi-trailer or trailer.

Floor elements of the type according to the invention are used in particular for box bodies of refrigerated vehicles or comparable transport vehicles. On the one hand, they assume the task of supporting the respective load to be transported. On the other hand, they must have a good heat-insulating effect, so that the heat transfer occurring via the bottom element remains as low as possible. In addition, such floor elements should have the lowest possible weight, so that the power supplied by the tractor can be used to the greatest extent possible for the transport of the respective load.

In order to meet these requirements, floor elements used for refrigerated box bodies, for example, are nowadays constructed in the manner of sandwich constructions. For this purpose, they have an upper cover layer whose free surface forms a loading surface on which a load to be transported can be lowered. To enable long service lives, the upper one is Cover layer usually covered with a light metal top layer, which comes into direct contact with the load to be transported alone.

The conclusion to the bottom of the vehicle forms in the known floor elements usually a lower cover layer. In the space between the upper and lower cover layer are aligned transversely to the longitudinal direction of the bottom member aligned and spaced from each other arranged transverse webs. These divide the existing between the cover layers space into chambers which extend transversely to the longitudinal direction of the bottom element.

These chambers are filled in the prior art with a foam filling. On the one hand, this foam filling ensures the required heat-insulating effect of the floor element. At the same time, the foam filling absorbs the substantial part of the load exerted by the load to be transported on the upper cover layer, and forwards it to the lower cover layer, which is supported on the chassis of the respective vehicle. The proportion which the foam filling has at the support of the upper cover layer is generally greater than the carrying portion of the transverse webs.

In practice, for the production of the floor elements therefore cuboid foam blocks are pre-produced, which are tailored according to the length and width of the chambers. Subsequently, the foam blocks and transverse webs are glued together in the required order, so that a green body provided with foam blocks and transverse webs is formed.

At the points where attachments, such as the vehicle chassis to be bolted to the bottom element, while the transverse webs are formed as cross member. The upper and lower cover layers are then glued to the prefabricated green body.

The advantage of the structure of a floor element for transport vehicles, which has been proven in practice in this way, is that the known floor elements have a low weight and at the same time a high load-bearing capacity as a result of the high carrying percentage of the foam filling and the comparatively small number of transverse webs. In addition, such constructed floor elements are characterized by good thermal insulation properties. However, foams that have sufficient load-bearing capacity are expensive and can only be processed with great effort.

Another way of making a floor element is from the US 5,772,276 known. In this known floor element, the upper cover layer is composed of prefabricated metal profiles, which are positively connected via corresponding form elements and additionally welded together. The cover layer thus formed is supported by transverse webs, which in turn are supported on a lower cover layer. The existing between the transverse webs spaces is filled by a foam, which carries in practical operation a substantial part of the load on the upper deck layer load. In a corresponding pressing device, the foam is filled in the spaces between the webs and expands while displacing the spaces in question existing gases until the rooms are completely filled with foam.

The advantage of the US 5,772,276 known design of a floor element for a box body is that the bottom element has a high load capacity. For this, however, a high weight and comparably high production costs must be accepted. Thus, the upper composed of the metal profiles must have sufficient strength to distribute the loads applied during operation on the upper deck layer sufficiently uniformly to the underlying foam filling.

Against this background, the invention was based on the object of specifying a Bodenrohelement and a method which allow it in a particularly suitable for mass production way to produce bottom elements of the type in question cost-effective. In addition, a cost-producible floor element should be created.

With respect to the Bodenrohelement this object has been achieved by the fact that such a Bodenrohelement is formed according to claim 1. Advantageous embodiments of the invention Bodenrohelements are given in the dependent claims on claim 1.

With respect to the bottom element, the object stated above has been achieved according to the invention in that such a bottom element according to claim 10 is trained. Advantageous embodiments of the invention Bodenrohelements are given in the claims back to claim 10.

Finally, the solution of the above-mentioned object with respect to the method according to the invention is that in the production of a floor element for a vehicle, the steps specified in claim 12 are completed. Advantageous embodiments of the method according to the invention are specified in the claims back to claim 12.

The invention is based on the idea that initially a hollow Bodenrohelement of transverse webs, an upper and a lower cover layer and a required for the longitudinal cover of the chambers on one of the longitudinal sides of the Bodenrohelements cover is assembled. If necessary, in the course of this operation, of course, other components can be mounted and arranged on the Bodenrohelement that are needed for the subsequent function of the finished floor element.

Only after the installation of the Bodenrohelements whose chambers are filled with foam. The supply and distribution of the foam to the chambers of the Bodenrohelements done via the disposed on one longitudinal side of the bottom member cover.

Thus, the displaced with the filling of the chambers of the Bodenrohelements with foam and the air released in the course of expanding and curing of the foam other gases Do not hinder expansion of the foam, the Bodenrohelement invention also has a vent through which these gases can escape from the chambers.

Accordingly, the invention provides a Bodenrohelement having an upper deck layer whose free surface forms a loading surface on which a load to be transported is abstellbar, a lower cover layer, which forms the conclusion of the bottom member to the underside of the vehicle, and transverse to the longitudinal direction Having the bottom member aligned and spaced from each other arranged transverse webs, which divide the existing space between the cover layers into chambers. According to the invention, a cover element is provided on one of the longitudinal sides of the bottom roughness element, which delimits the chambers on the respective longitudinal side. The cover is formed as a hollow profile and has a running in the longitudinal direction of the hollow profile longitudinal channel. This longitudinal channel is connected via at least one access opening with at least one of the chambers and has a connection opening for supplying flowable foam.

According to a particularly important embodiment of the invention a Bodenrohelement is characterized in that the cover extends over the occupied by the chambers length of the bottom member so that each of the chambers is associated with at least one of its access openings. This variant of the invention has the advantage that arranged on the respective longitudinal side of the Bodenrohelements only one component which is easy to prefabricate and assemble.

The vent opening through which the gas mixture formed during the filling of the chambers with foam, formed from air and the other released gases can escape from the chambers can basically be realized by the fact that the chambers of the Bodenrohelements on the provided with the cover first longitudinal side opposite side are open. During the filling process, a suitable tool can then be placed on this open side, which prevents the uncontrolled escape of foam and sucks the escaping gas mixture.

It is also conceivable to completely close the chambers on the longitudinal side opposite the first cover element and to connect the chambers to one another by corresponding connection openings in such a way that the gases flow through the chambers to a central vent opening, where they are sucked off.

Another particularly practical way to vent the chambers during filling with foam, moreover, is to arrange on the cover member for supplying the foam opposite side another cover, in which the chambers associated with the vent openings are formed. For this purpose, this cover element mounted on the longitudinal side of the floor tropical element has at least one ventilation opening for discharging gas, which is contained in at least one of the chambers assigned to this cover element.

In this case, with regard to the simplest possible handling and assembly, the cover element provided with the at least one ventilation opening preferably extends over the longitudinal side of the bottom roughening element such that each of the chambers of the bottom roughening element is associated with at least one of its vents.

For the invention according to the invention via the one designed as a hollow profile cover feeding and distribution of the foam on the chambers, it is sufficient if the cover has a single longitudinal channel, said longitudinal channel can be fed via one or more connection openings with foam. The uniformity of the distribution of the foam on the chambers of the Bodenrohelements can be assisted in that the position, the opening areas or the number of the individual chambers of the Bodenrohelements associated access openings of the connected to the connection opening for supplying foam covering depending on the distance of respective access opening to the connection opening or the volume of the respective chamber is varied. Complex inflow controls, which would otherwise be required for metering the amount of foam to be loaded into each chamber, can be avoided in this way.

The use according to the invention of the cover element to be connected to the foam supply for supplying and distributing the foam to the chambers to be filled can also be optimized in that the first cover element provided with the connection opening for supplying flowable foam has two mutually parallel and having longitudinal walls separated by a partition, which are interconnected via communication holes formed in the partition, and one longitudinal channel is connected to the chambers of the bottom scroll via the access ports, while the other longitudinal channel is provided with the port for supplying flowable foam. The existing for feeding the foam and interconnected longitudinal channels allow the manner of a cascade system precisely allocate the amount of foam required each section of the directly connected to the chambers longitudinal channel, so that in a continuous process in the chambers only the amount of foam actually required there passes ,

The amount of foam entering the chambers can be directly influenced by the fact that the number, size and position of their respective associated inflow openings is designed, for example, as a function of the volume of the respective chamber and its position relative to the connection via which the foam is supplied. For this purpose, the connection opening for supplying foam may have an overall larger opening area than the connection openings formed in the partition wall and the connection openings have an overall larger opening area than the access openings leading to the chambers. Also, for example, large-volume chambers may be associated with larger or more access openings than small-volume chambers.

The uniformly dense filling of the chambers with the foam rising in them during the filling can be assisted by the fact that in the vent opening gas permeable plug sits. This plug forms a barrier which prevents the foam reaching the vent opening from leaking out of the chamber in an uncontrolled manner. In this way, an increased pressure is created in the chamber, which ensures the formation of a high-density foam with a uniform pore distribution.

In principle, it is possible to produce the covering elements provided according to the invention from all materials which can be shaped into a profile and have the required insensitivity to the foam. However, the cover elements can be produced in a particularly cost-effective manner if they are produced from a plastic material, in particular a PVC material. The use of plastic material moreover has the advantage that the connection opening provided in each case for supplying the foam and the vent openings optionally provided in the second cover element for discharging the gases emerging from the chambers of the bottom piping element during filling can be easily achieved after the filling operation has ended permanently sealed tightly. This can be done for example by gluing a suitable cover or welding the respective opening. If necessary, reinforcing elements, such as ribs or the like, may be formed on the cover elements made of plastic, so that the respective cover element can absorb the forces occurring during expansion of the foam with minimized deformations.

A special feature of both a Bodenrohteils invention as well as a floor element according to the invention is that between the mutually associated contact surfaces of cover layers and transverse webs no foam traces are present, since the foam filling takes place only after the installation of the Bodenrohelements. This allows it to easily and with high productivity, the transverse webs at their upper and lower cover layer respectively associated upper and lower sides with the upper and lower cover layer to glue. It is particularly advantageous that the adhesive can evenly wet the entire adhesive surface, since it is free of foam, which could otherwise affect the effect of the adhesive.

Important for the success of the invention is also that the Bodenrohelement according to the invention before filling with foam is such that its spatial form substantially corresponds to the shape of the finished floor element, so that the Bodenrohelement is filled only with foam for the completion of the floor element. This approach makes it possible to prefabricate all the shape of the finished floor element determining single line precisely and assemble with high precision. The Bodenrohelement thus obtained has a high dimensional stability and can be mounted within the shortest cycle times.

At the same time, the invention makes it possible to manufacture the Bodenrohelement regardless of the particular characteristics of the foam. So can be used in the assembly of Bodenrohelements also such connection techniques, their effectiveness could be affected by an interaction with the foam. In particular, the procedure according to the invention allows the transverse webs to be adhesively bonded to the upper and lower cover layers with the use of adhesives which would not adhere properly to surfaces which had previously been wetted with foam.

• Bereitstellen eines erfindungsgemäßen Bodenrohelements,
• Positionieren des Bodenrohelements derart, dass sich das mit dem Längskanal versehene Abdeckelement in einer tieferen Position befindet als die gegenüberliegende Längsseite des Bodenrohelements,
• Befüllen der Kammern mit einem fließfähigen Schaum, der über die Abschlussöffnung zum Zuführen von Schaum in den Längskanal des in der tieferen Position befindlichen Abdeckelements geleitet wird, wobei die dem Bodenrohelement zugeführte Schaummenge derart bemessen ist, dass der Schaum im expandierten Zustand die Kammern des Bodenrohelements vollständig füllt, und
• Expandieren des den Kammern zugeführten Schaums, wobei der Schaum während seiner Expansion selbsttätig in den Kammern aufsteigt, bis die Kammern vollständig gefüllt sind, wobei während der Expansion des Schaums die in den Kammern enthaltenen Gase über mindestens eine Entlüftungsöffnung entweichen.

The method according to the invention for producing a floor element for a vehicle, such as a lorry, semi-trailer or trailer, accordingly comprises the following steps:

• Providing a floor roughing element according to the invention,
• Positioning the Bodenrohelements such that the provided with the longitudinal channel cover is in a lower position than the opposite longitudinal side of the Bodenrohelements,
• Filling the chambers with a flowable foam, which is passed through the end opening for supplying foam in the longitudinal channel of the lower position cover, wherein the Bodenrohelement supplied amount of foam is dimensioned such that the foam in the expanded state, the chambers of the Bodenrohelements completely fills, and
• Expanding the foam supplied to the chambers, wherein the foam during its expansion automatically rises in the chambers until the chambers are completely filled, during the expansion of the foam, the gases contained in the chambers escape via at least one vent opening.

According to the invention, the filling of the chambers of the prefabricated Bodenrohelements takes place against the direction of gravity. In this way, it is ensured that the foam which enters the chambers in the flowable state and which expands there, fills the chambers uniformly and completely. Thus, the foam rises in its expansion against gravity in the chambers. The pressure exerted by the advancing foam ensures that pores of uniform size distribution are established over the entire volume of the chambers.

The gravity effect utilized by the invention optimally occurs when the bottom tray member is positioned to be filled with the foam so that its chambers are substantially vertically aligned.

The uniformity of the filling of the chambers can be additionally supported by at least one of the transverse webs having a recess, via which the chambers separated from one another by the respective transverse web are connected to one another. About the recesses of the transverse webs, the chambers are connected to each other in the manner of communicating tubes, so that it automatically comes to a balance of the filled into the individual chambers foam volumes.

From the inventive idea to prefabricate a Bodenrohelement and then fill this Bodenrohelement with foam, it follows that in a bottom element, which is made based on a inventively designed Bodenrohelement, the chambers are filled with a foam filling, over the Longitudinal channel of the formed as a hollow profile first cover member has entered the chambers.

Typically, in a bottom element designed according to the invention, the covering element designed as a hollow profile, via which the foam is supplied, is substantially completely filled with foam.

As a sign of an optimally uniform and complete filling of the chambers of a floor element according to the invention can be considered when the foam is present at the at least one vent opening or even penetrated into it.

For the filling of the chambers of a floor element according to the invention has been found to be particularly suitable polyurethane foam. Such PU foams are available at low cost and not only have good thermal insulation properties. In addition, PU foams form closed pores in which moisture can not accumulate. PU foams thus prevent particularly effectively that, in the case of floor elements of the type according to the invention used in refrigerated vehicles, accumulation of condensation occurs in the region of the chambers.

Practical investigations have shown that PU foams with a bulk density of at most 55 kg / m ³ are sufficient for the purposes according to the invention, with foams having a bulk density of 45 kg / m ³ and less being preferred. In floor elements according to the invention, PU foams having a bulk density of 40-45 kg / m ³ could be detected as being practical.

In a bottom element filled with such a foam of reduced bulk density, the transverse webs largely absorb the load and convey it to the lower cover layer. For this purpose, the distribution and the distance of the transverse webs can be selected such that the transverse webs absorb a larger part of the load in practical use on the upper cover layer load as filled in the chambers foam filling. The displacement of the substantial bearing portion on the transverse webs makes it possible to use a foam for the filling of the chambers of a floor element according to the invention, whose carrying capacity is comparably low, the insulating effect is optimized at the same time, however. Such foams are much cheaper available and can also be much easier and less expensive to use than foams that are able to accommodate high loads. With the embodiment according to the invention is thus a floor element available, which can be produced particularly economically in use properties that meet the requirements occurring in practice safely.

Fig. 1

einen Sattelzug in einer perspektivischen Ansicht;

Fig. 2

den Sattelauflieger des in Fig. 1 dargestellten Sattelzugs in einer seitlichen Ansicht;

Fig. 3

den Sattelauflieger in einer perspektivischen Explosionsansicht;

Fig. 4

einen Ausschnitt eines in dem Auflieger gemäß Fig. 2 verbauten Bodenelements in einem Längsschnitt;

Fig. 4a

einen weiteren Ausschnitt des in Fig. 2 gezeigten Bodenelements in einem Längsschnitt;

Fig. 5

den Ausschnitt gemäß Fig. 4 in Draufsicht;

Fig. 6a

den Ausschnitt gemäß Fig. 4 bei abgenommener oberer Decklage in teilgeschnittener Draufsicht;

Fig. 6b

den Ausschnitt einer alternativen Ausgestaltung des Bodenelements bei abgenommener oberer Decklage in teilgeschnittener Draufsicht;

Fig. 7 - 9

das Bodenelement in verschiedenen Stadien seiner Befüllung mit Schaum;

Fig. 10

einen Querträger für das Bodenelement in seitlicher, teilweise aufgebrochener Ansicht;

Fig. 11

den Querträger gemäß Fig. 10 in einer ausschnittsweisen, längsgeschnittenen Ansicht;

Fig. 12

den Querträger gemäß Fig. 10 in einem Schnitt entlang der in Fig. 11 eingezeichneten Schnittlinie X1-X1;

Fig. 13

den Querträger gemäß Fig. 10 in einem Schnitt entlang der in Fig. 11 eingezeichneten Schnittlinie X2-X2;

Fig. 14

einen Quersteg bei der Montage auf der unteren Decklage des Bodenelements B;

Fig. 15

den Quersteg gemäß Fig. 14 in fertig auf der der unteren Decklage des Bodenelements B montierter Stellung;

Fig. 16

den Bereich des Anschlusses zwischen einem Bodenelement und einer Seitenwand des Sattelaufliegers in einem Schnitt quer zur Längsrichtung des Bodenelements;

Fig. 16a

einen Ausschnitt N von Fig. 16 mit einem Detail des in Fig. 16 dargestellten Anschlusses in einer vergrößerten Darstellung;

Fig. 16b,16c

jeweils eine alternative Ausgestaltung des in Fig. 16a gezeigten Details in einer zu Fig. 16a korrespondierenden vergrößerten Darstellung;

Fig. 17

den Bereich des Anschlusses zwischen dem Bodenelement und der Seitenwand des Sattelaufliegers in einem Schnitt, der an einer anderen Stelle als der in Fig. 16 gezeigte Schnitt quer zur Längsrichtung des Bodenelements geführt ist;

Fig. 18

den in Fig. 17 gezeigten Bereich des Anschlusses in einer frontalen, aus dem Innenraum auf diesen Bereich gerichteten Ansicht;

Fig. 19

den Bereich eines alternativ ausgeführten Anschlusses zwischen dem Bodenelement und der Seitenwand des Sattelaufliegers in einem Schnitt, der an einer anderen Stelle als der in Fig. 16 gezeigte Schnitt quer zur Längsrichtung des Bodenelements geführt ist;

Fig. 20

den Bereich einer weiteren Ausführung des Anschlusses zwischen dem Bodenelement und der Seitenwand des Sattelaufliegers in einem Schnitt, der an einer anderen Stelle als der in Fig. 16 gezeigte Schnitt quer zur Längsrichtung des Bodenelements geführt ist.

The invention will be explained in more detail with reference to an exemplary embodiments illustrative drawing. Each show schematically:

Fig. 1

a tractor trailer in a perspective view;

Fig. 2

the semitrailer of the Fig. 1 illustrated tractor trailer in a side view;

Fig. 3

the semi-trailer in a perspective exploded view;

Fig. 4

a section of a in the trailer according to Fig. 2 installed floor element in a longitudinal section;

Fig. 4a

another section of the in Fig. 2 shown floor element in a longitudinal section;

Fig. 5

the clipping according to Fig. 4 in plan view;

Fig. 6a

the clipping according to Fig. 4 with removed upper cover layer in a partially sectioned plan view;

Fig. 6b

the detail of an alternative embodiment of the bottom element with removed top cover layer in a partially sectioned plan view;

Fig. 7 - 9

the floor element at various stages of its filling with foam;

Fig. 10

a cross member for the floor element in a side, partially broken view;

Fig. 11

according to the cross member Fig. 10 in a fragmentary, longitudinally cut view;

Fig. 12

according to the cross member Fig. 10 in a section along the in Fig. 11 drawn section line X1-X1;

Fig. 13

according to the cross member Fig. 10 in a section along the in Fig. 11 Plotted section line X2-X2;

Fig. 14

a crosspiece during assembly on the lower cover layer of the bottom element B;

Fig. 15

according to the crosspiece Fig. 14 in finished on the lower cover layer of the bottom element B mounted position;

Fig. 16

the area of the connection between a floor element and a side wall of the semitrailer in a section transverse to the longitudinal direction of the floor element;

Fig. 16a

a section N of Fig. 16 with a detail of in Fig. 16 illustrated connection in an enlarged view;

Fig. 16b, 16c

each an alternative embodiment of the in Fig. 16a shown details in one too Fig. 16a corresponding enlarged view;

Fig. 17

the area of the connection between the floor element and the side wall of the semi-trailer in a section that is at a different location than that in Fig. 16 shown section is guided transversely to the longitudinal direction of the bottom element;

Fig. 18

the in Fig. 17 shown area of the terminal in a frontal, from the Interior view on this area;

Fig. 19

the area of an alternative connection between the floor element and the side wall of the semi-trailer in a section which is at a different location than in Fig. 16 shown section is guided transversely to the longitudinal direction of the bottom element;

Fig. 20

the area of a further embodiment of the connection between the bottom element and the side wall of the semitrailer in a section which at a location other than in Fig. 16 shown section is guided transversely to the longitudinal direction of the bottom element.

In the example described here, designed as a refrigerated transporter S consists of a known type of a tractor Z and a semi-trailer A.

The semitrailer A comprises a box body K, which is mounted on a chassis chassis C. The box body K insulates the interior I surrounded by it against the heat of the surroundings U. The box body K is made up of the basic elements "floor element B", "roof D", "longitudinal side walls L1, L2", "end wall W", that of the tractor Z is assigned, and "rear wall R" composed, which is arranged opposite to the end wall W. On the front wall W, a cooling unit M is mounted, which cools the interior I of the box body K. In the rear wall R, the doors are provided, over which the loading and Unloading of the box body K takes place. To support the uncoupled from the towing vehicle Z semi-trailer A in the front part on the underside US of the bottom element B fixed support wind V is provided.

The longitudinal side walls L1, L2 may be composed in known manner from individual segments, not shown here, whose length L of the box body K measured length corresponds to a fraction of the total length of the longitudinal side walls L1, L2, while their height is equal to the height of the longitudinal side walls L1, L2 is. If the following is the longitudinal side walls L1, L2, the relevant explanations apply to integrally formed longitudinal side walls as well as for individual segments composed of individual segments.

The bottom element B has an upper cover layer 1 which is formed by an upper cover layer 2 associated with the interior I of the box body K and a supporting layer 3 supporting the cover layer 2.

The cover layer 2 is composed of separately prefabricated molded parts 4,4a, which are prefabricated as flat profiles. In the mold parts 4,4a shaped elements, such as groove rails 4b, not shown threaded openings or similar elements for attaching and striking of lashing or other fasteners may be incorporated. These are preferably formed so that the loading surface F is substantially flat and free of protruding beyond projections. The molded parts 4, 4a extend in the longitudinal direction L of the bottom element B over its entire length and occupy each a fraction of its width b.

At their longitudinal edges, the mold parts 4,4a are welded to the respective adjacent molded part 4,4a. The welds 5 of the molded parts 4, 4a are designed, for example, as friction stir welding. This welding method makes it possible in a particularly cost-effective and effective manner to connect the flat aluminum moldings 4, 4a which are butt with their longitudinal edges over the entire length of the floor element, as far as possible avoiding heating-caused deformations of the mold parts 4, 4a to be joined together. By doing so, the friction stir welds 5 are performed from the side of the cover layer 2 assigned to the backing layer 3 of the cover layer 1, the root side of the friction stir welds 5 being associated with the loading surface F, the weld zones 5 visible from the interior I can be made largely smooth.

As an alternative to an aluminum material, the molded parts 4, 4a may also be made of a sheet steel. For this purpose, the individual molded parts 4, 4a can be formed, for example, by roll forming, rolling or another cost-effective method from correspondingly shaped sheet metal blanks.

On its free upper side, the molded parts 4, 4 a are provided with a regular profiling 6. This prevents people from slipping, which formed by the free surface of the cover layer 2 cargo area F of the bottom element B, for example, for loading and unloading in the semitrailer A each commit to be transported load T.

In the case that the molded parts 4, 4a have been produced from an aluminum material, for example by extrusion, the profile can be formed in the form of grooves extending in the longitudinal direction of the molded parts directly into the surface of the molded parts 4, 4a forming the loading surface F. Grooves extending transversely to the longitudinal direction L of the molded parts 4, 4a can be formed into the surface concerned by means of suitable tools during hot forming. Alternatively, these grooves may also be cut into the surface of the moldings by suitable machining methods, for example sawing or butting.

In the case that the mold parts 4, 4a are formed from steel sheets, a profile in the form of grooves aligned over the length of the mold parts 4, 4a or transversely thereto can also be formed in a simple manner on the shaped parts 4, 4a. Seen in cross-section, the molded parts preferably have a cross-section, in which the base of the grooves are respectively oriented at right angles to the side surfaces adjacent to the base surface, such as the support surface directly supporting the material to be transported to these side surfaces. The depth of the grooves is optimally designed so that even with fully loaded cargo area F sufficient amounts of air can circulate through grooves, for example, there to safely remove accumulating moisture.

The composite of the mold parts 4,4a cover layer 2 is bonded over the entire surface with the existing of a wood material support layer 3 of the upper cover layer 1. The thickness D3 of the base layer is in this case many times greater than the thickness of the cover layer 2. The essential contribution to the load-bearing capacity of the upper cover layer 2 is accordingly taken over by the base layer 3.

The support layer 3 is supported on transverse webs 7, 7 a, 7 b, 8. The transverse webs 7,7a, 7b, 8 are each made of a wood material. They have a cuboid, elongated basic shape and extend transversely to the longitudinal direction L aligned over the width b of the bottom element B. Their thickness is typically in the range of 9 - 15 mm.

At the points where attachments, such as the side members 9 of the chassis chassis C or the support of the landing gear V, are attached to the bottom US of the bottom element B, the transverse webs are formed as cross member 8.

At their upper cover layer 1 associated flat top, the transverse webs 7,7a, 7b and cross member 8 with their facing underside of the support layer 3 of the upper cover layer 1 each glued.

For positionally secure positioning of the transverse webs 7, 7 a, 7 b and cross member 8 on the upper cover layer 1, dowel openings 11 are formed in the supporting layer 3 from the underside thereof, in which dowels 12 sit with their upper dowel section 12 a. The dowels 12 are involved a paragraph 12b on the underside of the upper cover layer 1 addition. By the height of the shoulder 12b, the height H13 of a bonding gap 13 is defined, which receives the amount of adhesive required for bonding the transverse webs 7,7a, 7b, 8 respectively. At the shoulder 12b, a lower dowel portion 12c is formed, which is coaxially aligned with the dowel portion 12a, but has a smaller diameter than the dowel portion 12a.

Each crossbar 7 and cross member 8 are assigned at least two dowels 12. In the top of the transverse webs 7 and cross member 8 corresponding openings 14 are formed at the appropriate place, in which the respective lower dowel portion 12c of the associated dowel 12 engages. The dowels 12 have at their dowel portions 12a, 12b each latching projections 13 which engage inextricably with the rough walls of the respective dowel opening 11,14.

To ensure that the adhesive bond between the transverse webs 7,7a, 7b or the cross members 8 and the support layer 3 withstand shear loads acting from unfavorable direction, the transverse webs 7,7a, 7b and cross member 8 are each additionally form-fitting with the support layer 3 coupled. For this purpose, 1 depressions 3a are milled in the form of grooves in the underside of the support layer 3 of the upper cover layer, which extend transversely to the longitudinal direction L of the bottom element B. At the transverse webs 7,7a, 7b correspondingly shaped web-like projections 8u are formed, which engage from the support layer 3 associated upper side of the transverse webs 7,7a, 7b and cross member 8 positively into the depressions 3a. Depending on the loads occurring in practical operation, each transverse web 7,7a, 7b or cross member 8 may be associated with one or more depressions 3a, in which the respective crossbar 7,7a, 7b or cross member 8 engages with a corresponding number of projections.

The distance a1, a2, a3 of the transverse webs 7,7a, 7b and the cross member 8 to each other varies according to the loads that act on the bottom element B in practical use. Accordingly, in a retraction area G of the loading area F, which is assigned to the rear wall R and is driven on loading and unloading by a forklift vehicle, not shown here, the transverse webs 7a arranged at a smaller distance a1 than arranged outside the retraction area G transverse webs 7 or Cross member 8, which are placed at a greater distance a2. Correspondingly, the transverse webs 7b or the cross member 8 in the region of the bottom element B, in which a in practice on the towing vehicle Z resting chafing plate 14 is formed in the lower cover layer 10 of the bottom element B, if necessary, at a reduced distance a3, to be able to safely absorb the loads occurring there. The distance a1 of the transverse webs 7a in the retraction region G is typically 50-100 mm, in particular 60-80 mm, while the distance a2 of the transverse webs 7 in the normally loaded areas typically at 100-180 mm, in particular 120-160 mm, and the Distance a3 of the transverse webs 7b and cross member 8 in the region of the chafing plate 14, for example at 80 - 140 mm, in particular 100 - 120 mm, is located.

The lower cover layer 10 of the bottom element B is made of sheet steel. In the in Fig. 4 generally designated by "E1" areas, which are not subject to special loads in practical use, the thickness of the steel sheet is 0.6 - 0.8 mm, whereas the lower cover layer 10 in the in Fig. 4 generally referred to as "E2" and "E3", which are more heavily loaded in practical use, have thicknesses of 2 - 4 mm or 6 - 8 mm.

As steel sheet material for the lower cover sheet 10, known steel sheets from the field of automobile body manufacture come into consideration, which have a high strength with sufficient corrosion resistance. Such sheets are usually provided with a metallic corrosion protection layer, such as a hot dip galvanizing or fire aluminizing. In addition, they can be provided to further improve their corrosion protection with an organic coating. Such steel material is available in practice as a so-called "coil coating material".

The thickness increase of the lower cover layer 10 takes place in each case in the direction of the space limited between the upper and lower cover layers 1, 10, so that, viewed on the underside US of the floor element B in the longitudinal direction L, it is designed to be at most a single shoulder. In the production of the bottom element can be used as a simply designed press whose pressing surfaces are flat and in which no special precautions for the compensation of length tolerances of the bottom element B are required. Optimal is when the Bottom in the longitudinal and transverse directions is substantially completely smooth in a plane.

The height H8 of the transverse webs 7, 7a, 7b and cross member 8 in the regions E2, E3 in which the lower cover layer 10 has a greater thickness is correspondingly opposite the height H8 of the transverse webs arranged in the less heavily loaded regions E1 of the floor element B. 7,7a, 7b and cross beams 8 reduced, so that the loading surface F extends over the entire length of the bottom element B in a horizontal plane.

In order to realize the different thickness regions of the lower cover layer 10, the lower cover layer 10 is composed of different thickness, firmly interconnected sheet metal parts. These may, for example, be prefabricated steel sheets in the manner of tailored blanks, in which steel blanks of different strength and thickness are combined with one another. It is also conceivable to roll in the required thickness differences into the steel material of the lower cover layer 10 with a sufficiently flexible rolling process.

In this way (s. Fig. 4a ) formed in the front, the tractor Z associated portion of the lower cover layer 10, a sliding plate O extending from the front end of the bottom element B in the direction of the rear wall R to behind the kingpin Q, on the driving forces on the semitrailer A in driving be transmitted. The sliding plate O has a typical thickness of 4 mm.

The kingpin Q is supported by a squared in a top view scrubbing plate Q1, which is inserted into a correspondingly shaped cutout of the slide O so that their US underside surface associated as well as the corresponding surface of the slide plate O flush with the bottom US of the bottom element B. is aligned. The chafing plate Q1 has a typical thickness of 8 mm.

The scrubbing plate Q1 is fixed to beams Q2, Q3 formed by two cross-sectionally L-shaped beam parts Q4, Q5, respectively. The one support part Q4 is welded with its one leg with the top of the sliding plate O associated with the space limited between the cover layers 1, 10. At the same time, the support part Q4 is positioned so that its other leg, with its face oriented perpendicular to the top of the slide plate O, is at the edge defining the opening into which the chafing plate Q1 is inserted.

The respective second carrier part Q5 of the carriers Q2, Q3 is seated with its one leg on top of the chafing plate Q1 and is oriented such that the end face of the other leg aligned perpendicular to the chafing plate Q1 bears tightly against the end face of the other carrier part Q5.

The respective carrier parts Q4, Q5 of the carriers Q2, Q3 are fixedly and non-detachably connected to one another. For this purpose, for example, bolt connections Q6, Q7 may be provided. Alternatively, the carrier parts Q2Q3 can also be bolted together or welded. By the Division of the carrier Q2, Q3 in each case two carrier parts Q4, Q5, it is possible to pre-assemble the chafing plate Q1 with its associated support parts Q5 separated from the rest of the bottom element B.

In this pre-assembly, the scrubbing plate Q1 is tacked by spot welds Q8, Q9 to the respective support member Q5. The circumferential gap Q10 remaining between the chafing plate Q1 and the surrounding slide plate O may be sealed by a sealant to prevent the penetration of moisture into the interior of the bottom element B.

In the case where the scrubbing plate Q1 has to be cut out of the bottom member B due to wear or damage, the spot welds Q8, Q9 may be drilled or cut out of the scrubbing plate Q1. The chafing plate Q1 can then be easily removed from the bottom element B, wherein the originally assigned carrier parts Q5 remain in the bottom element B. Your now free US underside of the bottom element B respectively associated surface then forms a contact surface on which the new or repaired is re-attached by appropriate spot welds. As an alternative to spot welding, which can be produced in a particularly cost-effective manner, it is of course also possible to use other connections for connecting the scraper plate Q1 to the carrier parts Q5, which allow point-by-point fastening.

To secure the stop of the transverse webs 7,7a, 7b and cross member 8 on the lower cover layer 10 are there Stops 15 provided in the form of cross-sectionally U-shaped receptacles. The stops 15 may be prefabricated as separate sheet metal parts, which are attached to the designated location on the lower cover layer 10, for example by spot welding. Alternatively, it is also conceivable to form the stops 15 directly from the sheet of the lower cover layer 10.

The clear width of the U-shaped stops 15 is dimensioned such that between the seated in the stops 15 transverse webs 7,7a, 7b or cross members 8 and the free from the lower cover layer 10 protruding legs 15a, 15b of the stops 15 sufficient space available is to receive the adhesive J, with which the transverse webs 7,7a, 7b and cross member 8 are glued in the stops 15 with the lower cover layer 10.

In order to ensure a uniform distribution of the filled before the insertion of the transverse webs 7,7, a, 7b and cross member 8 in the attacks 15 adhesive J, can at the lower cover layer 10 associated underside of the transverse webs 7,7a, 7b and cross member 8 a Abteilelement 16 may be provided which extends along the center line over the entire bottom and dividing the insertion of the transverse webs 7,7a, 7b or cross member 8 in the attacks 15 there already existing adhesive J into two substantially equal halves. In this way, the adhesive J is forced to ascend in equal proportions in the free space between one leg 15a and the other leg 15b and the respective transverse web 7, 7a, 7b or cross member 8. As a result, such a full-surface bonding of the transverse webs 7,7a, 7b and cross member 8 in the attacks 15 ensured.

When in Fig. 15 illustrated embodiment, the dividing element 16 is realized in the form of a lamella, which sits in a molded into the transverse webs 7,7a, 7b and cross member 8 slot 17. Whose width is dimensioned so that the prepared in the ready for assembly state on the slot 17 beyond the partition member 16 is held with slight pressure in the slot 17. At the same time, the depth of the slot 17 is adjusted so that the Abteilelement 16 is inserted at fully seated in the stop crosspiece 7,7a, 7b and cross member 8 over its entire height in the slot 17.

Alternatively to using the in Fig. 5 it is also possible to use as Abteilelement 16a an elastic part, such as a lip seal or a foam element, which can be compressed during insertion of the respective crosspiece 7,7a, 7b or cross member 8 in the associated stop 15 , For this purpose, as a compartment element 16a, for example, a commercially available foam sealing tape can be used, which is covered on its top and bottom with an adhesive film. With one side, such a compartment element 16a can be glued to the respective transverse web 7, 7a, 7b or cross member 8. With its other side, the compartment element 16a adheres automatically when placing the respective transverse web 7a, 7b, 7 or cross member 8 with the lower cover layer 10 and enforces so particularly effective that the adhesive J spreads in the desired manner in the receptacle 15 ( Fig. 14 ). The transverse webs 7 and cross member 8 divide the space delimited between the upper cover layer 1 and the lower cover layer 10 into chambers 18 which extend across the width b of the floor element B and laterally through one of the transverse webs 7, 7a, 7b or cross member 8, respectively are limited.

The chambers 18 are completely filled with a foam filling SF, which is formed from commercial polyurethane foam. This is designed so that it makes at most a minor contribution to the carrying capacity of the floor element B.

Optimally, the foam filling SF of the chambers 18 acts essentially exclusively heat-insulating, so that the loads on the loading surface F are transferred essentially exclusively via the transverse webs 7, 7 a, 7 b and cross member 8 to the lower cover layer 10. For this purpose, the foam filled in the chambers 18 preferably has a bulk density of 40-45 kg / m ³ .

In particularly high-stress zones or with regard to an optionally desired reduction in the number of transverse webs 7, 7 a, 7 b, it may also be expedient to design the foam filling SF-forming foam so that it covers part of the load on the upper cover layer 1 mitträgt. For this purpose, PU foam with a density of up to 55 kg / m ³ can be used.

It is also conceivable to fill certain chambers 18, in which the carrying capacity of the foam filling SF is in the foreground, with a foam of higher carrying capacity, while other chambers 18 are filled with a foam which has a essentially exclusively thermally insulating, non-supporting foam filling SF forms.

In order to ensure uniform filling of the chambers 18, at least one recess 7c, 8a is formed in each of the transverse webs 7, 7a, 7b and cross member 8, via which, when the chambers 18 are filled with the then still liquid foam, a volume equalization between the chambers takes place 18 can come. For this purpose, the respective recess 7c, 8a is preferably arranged at that end of the transverse webs 7, 7a, 7b or cross member 8, which is assigned to the longitudinal side of the bottom element B, at which the filling of the chambers 18 takes place with foam.

The two upper corner regions 8b, at which the upper cover layer 1 associated upper side merges into the respective narrow side of the transverse webs 7,7a, 7b or cross member 8, are each bevelled so that the imaginary extensions of the inclined surfaces formed there 8c converge pointed roof shape each other.

The recess 8a, corner portions 8b and inclined surfaces 8c are in Fig. 9 illustrated by way of example for a cross member 8, but are also found in the transverse webs 7,7a, 7b.

The cross member 8 have a main body 8d, which is like the transverse webs 7,7a, 7b made of wood material. The basic body 8d has, at the same height H8 and width B8 as the simple transverse webs 7, 7a, 7b, a greater thickness D8. In this way, the cross member 8 can safely absorb the loads acting on them in practical operation. Alternatively to the use of a wood material, the transverse webs 7, 7 a, 7 b and the main body of the cross member 8 can also be made of a different material, such as plastic. This can be indicated on the one hand for reasons of cost or reasons of availability of the required wood materials. On the other hand, the risk of the formation of thermal bridges in the region of the cross member 7 and cross member 8 can be reduced by the choice of alternative materials for the transverse webs 7 and cross member 8. For this purpose, it is also conceivable to combine a wood-based material with a highly heat-insulating material or to manufacture the transverse webs 7, 7 a, 7 b or cross member 8 from a fiber-reinforced mixed material.

In the base 8d of the cross member 8 are recesses 8e, 8f formed at the points at which the respective cross member 8 is screwed, for example, with the side rails 9 of the chassis chassis C. The recesses 8e, 8f are each formed as passage openings which are completely surrounded by the material of the base body 8d and have an elongated shape.

In each of the recesses 8e, 8f, a connection element 8g, 8h is seated in a form-fitting manner. The connecting element 8g has a plate-shaped basic shape adapted to the elongate shape of the recess 8e assigned to it. At its the contact surface 8i, with the respective cross member 8 is on the lower cover layer 10, associated underside are at regular intervals spaced from each other arranged projections 8j formed, with which the connecting element 8g positively engages in correspondingly shaped depressions of parallel to the footprint 8i extending base surface of the recess 8e engages.

Against a lateral displacement from the recess 8e, the connecting element 8g is additionally secured by two plate-shaped securing elements 8k, 8l, which abut the side surfaces 8m, 8n of the cross member 8 and are screwed firmly to the connecting element 8g.

The connecting element 8h likewise has an elongated shape which is wedge-shaped in cross-section, with its underside associated with the contact surface 8i extending parallel to the contact surface 8i, while its upper side is aligned obliquely with respect to the contact surface 8i. Accordingly, the recess 8f associated with this connection element 8h is wedge-shaped in cross-section, so that the connection element 8h is seated in a form-fitting manner in the recess 8f. Against a lateral displacement from the recess 8f addition, the connecting element 8h is protected on the one hand by an integrally formed on it shoulder 8o, which rests against the associated side surface 8n of the main body 8d. On the other hand, on the side 8o opposite the thinner side, a screw 8p is screwed into the connecting element 8h, which rests with its screw head against the side surface 8m of the main body 8d assigned to it.

In the connection elements 8g, 8h are each formed at a distance from each other two threaded holes. In each of these a screw 28 is screwed, with which the respective longitudinal member 9 is fixed to the bottom element B.

The screws 28 are each guided through an opening 8q, which are formed from the footprint 8i starting in the main body 8d. In the openings 8q each sit a sleeve 8r, 8s, which is made of steel. The sleeves 8s, 8r extend in the assembled state each over about half the length of the opening 8q.

In the area of the contact surface 8i associated end of the opening of the sleeves 8r, 8s, an O-ring seal 8t is used in each case, which prevents the penetration of moisture into the sleeve opening.

The O-ring seal 8t is positioned such that the retracted in the direction of the interior of the bottom member edge of the stamped for the respective screw 28 opening 10a of the lower cover layer 10 abuts the O-ring seal 8t. In this way, the open cut edge 10b of the opening 10a, which is no longer protected by the corrosion protection layer of the lower cover layer, is protected against contact with the moisture of the environment.

During the bonding of the respective transverse web 7, 7 a, 7 b or cross member 8, a third function of the O-ring seal 8 t is to protect the sleeve opening against the penetration of adhesive J. For this reason, the sleeves 8r, 8s, as in Fig. 10 shown before the bonding in the transverse webs 7,7a, 7b and cross members 8 each pre-assembled so that they are inserted only over part of their length in the opening 8q and with its collar and its seated therein O-ring seal 8t with a distance stand the footprint 8i. To this Way set the collar of the sleeves 8r, 8s with the O-ring seals 8t on the base of the U-shaped stops 15 before the transverse webs 7,7a, 7b and the cross member 8 have reached their final position in the stops 15.

Of course, the triple function of the O-ring seal 8t may also be accomplished by three separate seals, one for sealing the sleeve opening against ambient moisture ingress, the second for sealing the open cut edge 10b against the ambient humidity and the third thereto is to prevent the penetration of adhesive J in the sleeve opening.

The connection elements 8g, 8h absorb the forces transmitted by the screws 28 used as connecting elements and guide them predominantly as compressive forces into the basic body 8d of the cross members 8.

On their longitudinal sides, the chambers 18 are covered by a respective cover element 19,20. The cover 19,20 are formed as identical hollow sections. They are preferably made of inexpensive plastic material, such as a PVC material. At their ends, the cover 19,20 are each sealed.

When in Fig. 6a and Fig. 16 illustrated embodiment, the cover 19,20 each have a extending over its entire length longitudinal channel 21.

At the in Fig. 6b In the variant shown, the cover elements 19, 20 next to the first longitudinal channel 21 each still have a second longitudinal channel 22 which extends parallel to the first longitudinal channel 21. The longitudinal channels 21,22 are separated by a partition wall 23. In Fig. 6b For reasons of clarity, the longitudinal channels 21, 22 are shown side by side. However, they can also be positioned one above the other.

The each adjacent to the chambers 18 of the bottom member B longitudinal channel 21 of the cover 19,20 is connected via access openings 24 with the respective adjacent chamber 18.

The foam is supplied via connection openings 26, which are each formed in the outer wall of the cover 19. The size and arrangement of the connection openings 26 is chosen so that in the respective existing longitudinal channel 21,22 each have a foam volume flow is available sufficient to evenly connected to the longitudinal channel 21 to the directly connected to these chambers 18 of the bottom element B with foam supply.

When in Fig. 6a In the embodiment shown, the size of the opening areas of the access openings 24 increases with increasing distance e from the respectively adjacent connection opening 26.

When in Fig. 6b On the other hand, if necessary, two or more access openings 23 are assigned to the chambers 18 of the larger-volume bottom element B, whereas those in the retraction area G, for example, are assigned existing chambers 18 are connected with a smaller volume in each case only via an opening 24 with the longitudinal channel 21. In the same way, it would also be conceivable to supply the larger-volume chambers 18 with an access opening 24 with a larger diameter than the smaller chambers 18.

When in Fig. 6b In the embodiment shown, the longitudinal channels 21, 22 of the cover elements 19, 20 are connected to one another via connection openings 25 formed in the partition wall 23. The size and position of the connecting openings 25 is chosen so that supplied via the longitudinal channel 22 supplied foam in sufficiently large volume flows to the individual sections of the longitudinal channel 21, from which the foam is then distributed to the chambers 18 of the bottom element B. In practice, the opening area of the connection openings 25 is larger than the opening area of the access openings 23.

Both at the in Fig. 6a as well as in the Fig. 6b In the embodiment shown, it is thus possible, with the aid of the cover element 19 designed as a hollow profile, to distribute a flowable foam uniformly over a relatively small number of connection openings 26 over a large number of chambers 18 of the bottom extrusion element 19. By varying the size, arrangement and number of access openings 24, taking into account their position relative to the respective connection opening 26 and the volume of the chambers 18 is in the in the FIGS. 6a and 6b shown embodiments, a uniform filling of the chambers 8 with foam guaranteed even if the foam only one measured by the number of Chambers 18 small number of connection openings 26 is supplied.

Since the filling of the chambers 18 takes place only via one of the cover elements 19, 20, it would be sufficient if only the cover element 19 used for this purpose would be designed as a hollow profile in the manner described above. In contrast, the other cover element 20 could be designed as a simple cover plate. In this only sufficiently large vents would have to be formed through which the gases can escape, which are displaced by the filled into the chambers 18 foam or released. It would also be conceivable to completely dispense with the second cover element 20 if, when filling the chambers 18, a tool is available which closes the chambers 18 on their side opposite the cover element 19 and which are present in the chambers 18 and displaced by the foam Suction gases. In view of a simplification of the production and the symmetry of the shaping, however, it may be expedient to form both cover elements 19, 20 as explained here as identical hollow profiles.

In the case of the cover element 20, the access openings 24 leading to the chambers 18 serve as vent openings, via which the gases present in the chambers 18 can flow out, and the connection openings 26 for suctioning off the gases with the aid of a suction device, not shown here. In order to prevent leakage of undesirably large amounts of foam from the respective access openings 24 of the cover 20 during filling of the bottom element B are in the Access openings 24 of the cover 20 gas permeable plug 27 is provided. These can be made, for example, from a close-meshed grid or an open-cell foam material, the grid or pore size is so dimensioned that they prevent the passage of larger amounts of foam, but allow the gases flowing out of the chambers 18 pass unhindered. From the cover element 20, the gas mixture flowing out of the chambers 18 exits via the connection openings 26 formed in the outer wall of the cover element 20.

To produce a bottom element B, first a hollow bottom element BR, which has not yet been filled with foam, is produced. For this purpose, a cover layer 2, which is composed in the manner already explained above of welded aluminum moldings 4,4a, and a delivered as a wood panel support layer 3 are glued together. In the transverse webs 7,7a, 7b and cross members 8 associated underside of the support layer 3 required for the subsequent positioning of the transverse webs 7,7a, 7b and cross member 8 dowel openings 11 are already formed.

For bonding, the support layer 3 is coated on its top layer 2 associated upper side with adhesive. Subsequently, the cover layer 2 is placed and pressed with the support layer 3 until the adhesive has cured and cover layer 2 and support layer 3 are permanently connected to each other to the upper cover layer 1.

In the dowel holes 11, a dowel 12 is now used in each case. Subsequently, on the cross members 7,7a, 7b and transverse webs 8 associated underside of Support layer 3 at the points at which the relevant parts are to be positioned, applied adhesive and the transverse webs 7,7a, 7b and cross member 8 positioned at the positions provided for each of them. The seated in the support layer 3 of the upper cover layer 1 dowels 12 engage in their associated openings 14 of the transverse webs 7,7a, 7b and cross member 8 and secure the positionally correct arrangement of the respective crosspiece 7,7a, 7b and cross member 8 and the transverse gap 13th

Then the prefabricated from steel sheets lower cover layer 10 is placed on the transverse webs 7,7a, 7b and cross member 8. For this purpose, a sufficient amount of adhesive J is previously filled in the cross-sectionally U-shaped stops 15, wherein the stops 15, are placed in the cross member 8, the points at which openings 10 a are omitted so far that the openings of a glue-free edge region are surrounded, whose diameter is at least equal to the outer diameter of the collar of the sleeves 8r, 8s of the cross member 8. As a result, the sleeves 8r, 8s projecting opposite the contact surface 8i engage with their O-ring seal 8t and the end face of their collar on the adhesive-free edge region. In this way, the O-ring seal 8t prevents the adhesive, which subsequently automatically distributes itself in the abutments 15 described above, from entering the sleeve opening.

In order to accelerate the curing of the adhesive between the existing wood-base layer 3 and the existing aluminum cover layer 2, the support layer 3 is in front of the application of the adhesive in a

Continuous furnace heated to a temperature above ambient temperature. The greater the temperature difference between the ambient temperature and the temperature of the wood part to be bonded, the faster the adhesive hardens. Typically, the temperature difference is at least 10 ° C. At a temperature of 10 ° C above the ambient temperature of the base layer 3 temperature halves the curing time.

In this case, the temperature to which the support layer 3 is heated, of course, adjusted so that despite its elevated temperature between the order and the curing of the adhesive sufficient time for joining the parts to be bonded together remains.

The temperature compensation occurring after the cold cover layer 2 has been placed on the base layer 3 is low due to the low mass of the cover layer 2 compared to the base layer 3 and the low thermal conductivity of the adhesive. If necessary, it can be compensated for by increasing the temperature to which the base layer 3 is heated by the temperature reduction occurring when the cover layer 2 is placed. In this case, an unfavorable for the success of the bonding, resulting from the heat transferred from the heated support layer 3 heat expansion of the cover layer 2 can be prevented by the cover layer 2 is cooled during the pressing of the support layer 3 with the cover layer 2.

In the above for the bonding of the cover layer 2 with the support layer 3 of the upper cover layer 1 described Way, the other parts to be bonded together can be heated when shortened curing times of the adhesive are sought in terms of compliance with short cycle times in a standard production of floor elements according to the invention.

Finally, in each case one of the cover elements 19, 20 is fastened in the manner explained above on the longitudinal sides of the floor slaving element BR.

The finished bottom raw element BR (thus obtained) Fig. 7 ) is then pivoted about its longitudinal axis LA until the upper and lower cover layers 1, 10 are each aligned vertically and the covering element 19, via which the foam is subsequently introduced, is arranged at the lowest point.

The Bodenrohelement BR is in this position in a pressing tool P with two mold halves P1, P2, of which presses a tool half P1 on the newly formed free top of the cover layer 1, while the other tool half P2 on the newly trained bottom US lower Top layer 10 acts. Due to the fact that the upper cover layer 1 and the lower cover layer 10 are substantially flat on the sides on which the respective mold half acts, the contact surfaces of the tool halves P1, P2 can also be flat. Length tolerances of the very long Bodenrohelements BR can be compensated by a corresponding excess of the contact surfaces of the pressing tools P1, P2 in the longitudinal direction L readily. This is still the case, if in each case at most one paragraph on the Underside US lower cover layer 10 or cargo area F of the upper cover layer 1 is present. If such a shoulder is present on the respective side of the cover layers 1, 10, the respective contact surface of the tool halves also has a corresponding shoulder, from which the length tolerances are then compensated, without the need for any special measures.

Now flowable PU foam is passed into the cover 19 via the connection openings. When in Fig. 6a In the embodiment shown, the foam passes from there directly into the chambers 18 Fig. 6b on the other hand, it first passes into the outer longitudinal channel 22, from which the foam passes via the connecting openings 25 into the longitudinal channel 21 of the cover element 19. About the longitudinal channel 21 of the foam then enters the chambers 18 of the Bodenrohelements.

In both embodiments, the size, location, and number of ports 26, optional communication ports 25, and access ports 24 leading to the chambers 18 are selected to substantially uniformly increase the foam in the chambers 18 during the filling process. To equalize the filling level of the chambers 18 contributes that it comes on the adjacent to the cover 19 arranged recesses 8a of the transverse webs 7,7a, 7b and cross member 8 automatically to a compensating movement between the filled into the chambers 18 of the Bodenrohelements ER foam volumes ( Fig. 8 ).

Upon completion of the filling process, the foam filled in the chambers 18 begins to expand. It rises against the force of gravity in the chambers 18 until it reaches the opening serving as a vent opening 24 of the cover 20. The plug seated in the access openings 24 of the cover member 20 prevents larger amounts of foam from entering the cover member 20, but allows the gases released during the expansion of the foam and the air contained in the chambers 18 to pass through the expanding foam from the chambers 18 are urged. The gases emerging from the chambers 18 are sucked off in a controlled manner via the connection opening 26 of the cover element 20 and blown off into the environment after suitable filtering.

By preventing the foam from escaping freely from the chambers 18, a particularly dense and compact foam filling results in the chambers 18.

After the time required for the expansion and curing of the foam, a finished floor element B is available, the chambers 18 of which are filled with the foam filling SF ( Fig. 9 ). During the expansion and curing phase, the bottom element B can already be transported to the next processing station.

In the finished floor element B, the covering element 19, via which the foam feed has taken place, and the chambers 18 are completely filled with a foam filling SF, while the covering element 20, via which the chambers 18 extend from the chambers 18 leaked gases have been dissipated, if necessary, is incomplete filled with foam.

The molded along the longitudinal side walls L1, L2 moldings 4a of the cover layer 2 of the upper cover layer 1 are different from the other moldings 4, from which the cover layer 2 of the upper cover layer 1 is composed, inter alia, that in their along the respective longitudinal side wall L1, L2 extending edge portion a paragraph 29 is sunk. On the support surface 29a of the paragraph 29 is in each case a cross-sectionally L-shaped base rail 30 with its the loading surface F associated leg 31. The depth T29 of the paragraph 29 corresponds to the thickness of the leg 31, so that the free top 32 of the leg 31 in Aligned substantially flush with the loading surface F is aligned. At the same time, the width B29 of the heel 29 is adapted to the width of the leg 31 so that the skirting board 30 can be set with force in the paragraph 29 with play. Their respective longitudinal side wall L1, L2 associated leg 33 rests against the relevant longitudinal side wall L1, L2 and is glued to this.

By the top 32 of the leg 31 of the skirting board 30 is aligned substantially flush with the loading surface, on the one hand, the accumulation of dirt around the transition region between the leg 31 and the loading surface F is avoided. In addition, hinder in this arrangement, no edges of Skirting board 30 the loading and unloading of the box body B.

To further improve the hygienic safety of the connection of the skirting board 30 to the loading surface F, the gap existing in the region of the transition between the leg 31 and the loading surface F is closed by a longitudinal seam weld 34. So that this also does not protrude beyond the loading surface F, a channel 35 is formed in the respective molding 4a at the transition from the shoulder 29 to the loading surface F, which is surmounted by the front edge of the leg 31. Molten metal accumulating during the production of the longitudinal seam weld 34 sags in this channel 35, so that the longitudinal seam weld 34 is planar on its free upper side and merges substantially flush into the adjacent upper side 32 of the leg 30 and the loading surface F. In technical language, the channel 35 is also referred to as "welding beard support".

The skirting board 31 not only protects the edge area between the floor element B and the respective longitudinal side wall L1, L2, but also serves to reinforce the connection of the longitudinal side wall L1, L2 to the floor element. The latter function is supported by the fact that below the paragraph 29 to the molding 4 integrally a support profile 36 is integrally formed. The profile 36 has a first leg 36a, which, starting from the respective longitudinal edge of the cover layer 2, protrudes into the base element B oriented substantially at a right angle to the loading surface F. Between the loading surface F remote from the end of this leg 36a and the upper cover layer 2 extends another leg 36b of the support profile 36. This leg 36b is bevelled and arranged such that it is supported on the existing on the narrow sides of the transverse webs 7,7a, 7b and cross member 8 inclined surfaces 8c. At the respective longitudinal side wall L1, L2 associated outer surface of the leg 36a is the relevant longitudinal side wall L1, L2 and is there glued to the profile 36 and concomitantly with the bottom element B.

There is in each case a distance between the respective cover element 19, 20 and the respectively associated support profile 36, whose clear width a36 is dependent on the total thickness DL1 of the longitudinal side wall L1. These are installed in different thicknesses depending on the required insulating effect and the load to be absorbed by them. In order to be able to exploit the maximum permissible width of the box body K independently of the respective total thickness DL1, the longitudinal edge of the upper cover layer 1 is displaced more or less far from the longitudinal edge of the lower cover layer 10 as a function of the respective total thickness DL1. Accordingly, the clear width a36 between the support profile 36 and the respective cover 19,20 is different.

To bridge this distance foam-tight, according to the in Fig. 16 and Fig. 16a a variant made of plastic, strip-shaped transition piece 37 is provided, which engages with its one longitudinal edge form-fitting manner in a molded into the respective cover member 19,20 groove, while it with its other longitudinal edge also positively in one in the respective support profile 36th molded groove sits. This embodiment has the advantage that only one other transition piece 37 with otherwise identical design of the support profiles 36 and cover 19,20 must be used when a longitudinal side wall L1 to be installed with a different thickness.

Alternatively, it is also possible, a corresponding transition piece 37a in one piece to the respective cover member 20 (FIG. Fig. 16b ) and to make this engage in the groove of the support profile 36, or conversely, a transition piece 37b integrally formed on the respective support profile 36 and to engage this in the groove of the cover ( Fig. 16c ).

In order to secure the load T to be transported in the interior I of the box body K, so-called "load securing eyes" can be formed on the longitudinal side walls L1, L2. This is as a stop for a stop means, such as a hook or anchor, a lashing, such as a lashing or the like, serving stopper openings 38, the (s. Fig. 17,18 ) In the embodiment described here in the longitudinal side walls L1, L2 at the level of the voltage applied to the respective longitudinal side wall L1, L2 leg 33 of the skirting board 30 in the interior I associated inner sheet steel existing cover layer 39 of the respective longitudinal side wall L1, L2 are formed. The stop openings 38 are guided both by the inner cover layer 39 and by the adjoining legs 33 of the base strip 30.

In order to accommodate heavy loads and high clamping forces sitting on the side facing away from the interior I of the box body K side of the inner cover layer 39 as an aluminum casting prefabricated reinforcing member 40 which has a rest on the relevant side reinforcing plate 41. In this reinforcing plate 41, an opening 42 is formed, which covers the molded into the inner cover layer 39 and the skirting board 30 stop opening 38. The reinforcing plate 41 is designed so that it overlaps with its lower portion with the bottom member B in order to ensure maximum support of the reinforcing member 40. In this case, the skirting board 30, the inner cover layer 39 of the longitudinal side wall L1 and the reinforcing plate 41 are integrally connected to one another via a weld around the edge of the stop opening 38.

The reinforcing member 40 has in addition to the reinforcing plate 41, a receptacle 43 which is formed in the manner of a pocket and is aligned with its lower edge 43 a substantially flush with the lower edge portion of the stop opening 38 in the direction of gravity. This prevents accumulations of dirt and cleaning agent in the region of the receptacle 43. On the other hand, such a hook inserted into the stop opening 38, not shown here, can be supported on the lower edge 43a of the receptacle 43. In this way, he sits captive in the stop opening 38 and is already supported with its tip on the reinforcing plate 41.

The respective clamping means can thus be stretched by a person alone, while the hook is securely held in the stop opening 38. Since the pocket-shaped receptacle 43 surrounds the opening with a sufficient distance for easy insertion of the hook, it is ensured that the hook does not violate the foam filling of the respective longitudinal side wall L1. On its side facing away from the interior I side, the reinforcing plate 40 is stiffened by stiffening ribs 45.

In order to allow a maximum thickness DL1 of the longitudinal side wall elements L1, L2, is in the in the Figures 19 and 20 shown in the adjacent to the bottom element B area of the inner cover layer 39 of the longitudinal side wall elements L1, L2 in the longitudinal direction L extending paragraph 46 with a contact surface 47 for attaching the respective side wall element L1, L2 associated with a leg 33 of the L-shaped base skirting 30th formed. Both in the Figures 19 . 20 illustrated embodiments corresponds to the depth T46 of paragraph 46 of existing in the region of the upper free longitudinal edge of the leg 33 of the skirting 30 least thickness D33 of the leg. According to the embodiment Fig. 19 At the same time corresponds to the height H47 of the contact surface 47 of paragraph 46 to uaf a slight excess of the height of the leg 33 of the seat 47 seated pedestal strip 30. In this way, the pedestal strip 30 can be easily placed on the contact surface 47 and glued to it with ease become. A hygienic seal between the top The boundary edge of the shoulder 46 and the free longitudinal edge of the leg 33 existing joint can be done, for example, that there is a longitudinal seam welding performed or a corresponding sealant is filled.

To ensure that there is no deformation in the region of the upper boundary edge of the shoulder 46 as a result of on the side walls L1, L2 on the side facing away from the interior I side of the inner cover layer 39 of the respective side wall element L1, L2 a reinforcing plate 49 placed by the inner cover layer 39 is stiffened in the region of the transition of the abutment surface 47 into the surface of the inner cover layer 39 lying outside of the shoulder 46. This reinforcing plate 49 extends over the entire length of the shoulder 46 extends.

This in Fig. 20 embodiment shown differs from that in Fig. 19 shown in that in the embodiment of Fig. 20 the height H46 of paragraph 46 is so much greater than the height of the leg 33 of the skirting board 30, that sits above the leg 33 and at a distance from this within the paragraph one of a sufficiently solid steel material load securing rail 50. The load securing rail 50 is designed so that it can also absorb high lashing forces. It lies with its upper longitudinal edge on the upper boundary edge of the shoulder 46 and thus takes over in addition the stiffening function, which in the embodiment of Fig. 19 is satisfied by the reinforcing plate 49. With the respective longitudinal side wall L1, L2 the load securing rail 50 is glued or welded.

The additional thickness of the respective side wall L1, L2 made possible by the arrangement of the leg 33 in the shoulder 46 leads to a significant increase in the k-value of the longitudinal side walls L1, L2, without any reduction in the volume of the interior I effectively usable for the load the box body K is accompanied. The protection of the respective side wall L1, L2 against damage during loading and unloading is thereby ensured that the leg 33 in the region of its transition to the standing on the cover layer 2 of the bottom member B leg 31 has a thickness which is greater than its Depth T46 of paragraph 46 corresponding thickness D33. Accordingly, the leg 33 protrudes in the region of the transition to the leg 31 of the base strip 30 in front of the inner cover layer 39 and holds the material loaded in the inner space I at a distance from the respective side wall L1, L2. reference numeral 1 upper cover layer of the bottom element B 2 Cover layer of the upper cover layer 1 3 Supporting layer of the upper cover layer 1 3a depressions 4,4a Molded parts (flat profiles) 4b Slot Profile 5 welds 6 profiling 7, 7a, 7b Transverse webs of the floor element B 7c Recess of the transverse webs 7,7a, 7b 8th crossbeam 8a Recesses of the cross member 8 8b Corner regions of the cross member. 8 8c Sloping surfaces of the cross member. 8 8d Basic body of the cross member 8 8e, 8f Recesses of the body 8c 8g, 8h connection elements 8i footprint 8j projections 8k, 8l fuse element 8m, 8n faces 8o paragraph 8p screw 8q openings 8r, 8s shell 8t ring seal 8u projections 9 Side member of chassis chassis C 10 lower cover layer of the floor element B 10a Openings of the lower cover layer 10 10b Cut edge of the opening 10a 11 openings 12 dowel 12a Upper dowel section 12b Paragraph of the anchor 12 12c lower dowel section 13 bonding gap 14 chafe plate 15 attacks 15a, 15b Legs of the attacks 15 16,16a compartment elements 17 slot 18 Chambers of the floor element B 19.20 cover 21.22 Longitudinal channels of the cover 19th 23 partition wall 24 access openings 25 Connecting openings of the partition wall 23rd 26 Connection openings for the foam supply 27 Plug 29 paragraph 29a footprint 30 Plinth skirting board 31 Legs of the skirting board 32 Top of thigh 31 33 Legs of the skirting board 34 longitudinal seam 35 channel 36 profile 36a Legs of the profile 36 36b Legs of the profile 36 37,37a, 37b Transitions 38 stop openings 39 Inner cover layer of the longitudinal side walls L1, L2 40 reinforcing part 41 reinforcing plate 42 Opening of the reinforcing plate 41 43 admission 43a Lower edge of the picture 43 44 welding 45 stiffening ribs 46 Paragraph of the longitudinal side wall element L1 47 Investment area of paragraph 46 48 Top of thigh 33 49 Support panel 50 Load safety rails A Semitrailer of the semitrailer S a1, a2, a3 Distances of the transverse webs 7 or cross member. 8 to each other a36 clear width B Floor element of the trailer A B Width of the floor element B B8 Width of the cross member 8 and transverse webs. 7 BR Bodenrohelement C Chassis chassis of trailer A D3 Thickness of the base layer 3 D8 Thickness of the cross member 8 D33 Smallest thickness of the leg 33 DL1 Total thickness of the side wall L1 E1, E2, E3 Areas of varying load lower cover layer of the floor element B e respective distance between the connection opening 26 and the respectively associated access openings 24th F Loading surface of the floor element B G Retraction area of the loading area F H8 Height of the cross member 8 H13 Height of the adhesive gap 13 H47 Height of contact surface 47 I Interior of the box body K K Box body of semitrailer A L Longitudinal direction of the floor element B L1, L2 Long side walls of the box body K LA Longitudinal axis of the floor element B M cooling unit O sliding plate P press tool P1, P2 Tool halves of the pressing tool P Q kingpin Q1 chafe plate Q2, Q3 carrier Q4, Q5 L-shaped carrier parts of the carriers Q2, Q3 Q6, Q7 bolted connections Q8, Q9 spot welds Q10 Gap R Rear wall of the box body K S Semitrailer of the box body K SF foam filling T load to be transported T28 Depth of paragraph 28 T46 Depth of paragraph 46 U Surroundings US Bottom of the floor element B V Landing gear W Front wall of the box body K Z Tractor of the semitrailer S

Claims (15)

Bodenrohelement for a vehicle, such as a truck, semi-trailer (A) or trailer, - With an upper cover layer (1), the free surface forms a loading surface (F) on which a load to be transported (T) is abstellbar, - With a lower cover layer (10), which forms the conclusion of the bottom element (B) to the bottom (US) of the vehicle (S), and - With transversely to the longitudinal direction (L) of the bottom element (B) aligned and spaced from each other arranged transverse webs (7,7a, 7b, 8), which divide the space between the cover layers (1,10) existing space in chambers (18),
characterized, - That on a longitudinal side of the Bodenrohelements (BR) a cover member (19,20) is present, which limits the chambers (18) on the relevant longitudinal side, - That the cover (19) is formed as a hollow profile and in the longitudinal direction (L) of the hollow profile extending longitudinal channel (21,22) connected via at least one access opening (24) with at least one of the chambers (18) is and has a connection opening (25,26) for supplying flowable foam and - That a vent opening (24,26) is provided for discharging gases contained in the chambers (18). Bodenrohelement according to claim 1, characterized in that the cover (19) extends over the chambers of the (18) occupied length of the bottom element (B) so that each of the chambers (18) is associated with at least one access opening (24). Bodenrohelement according to claim 1 or 2, characterized in that in the second cover (20) at least one vent opening (24) for discharging gas is formed, which is contained in at least one of this cover member (20) associated with chambers (18). Bodenrohelement according to any one of the preceding claims, characterized in that the second cover (20) extends over the chambers of the (18) occupied length of the bottom element (B) so that each of the chambers (18) associated with at least one vent opening (24) is. Bodenrohelement according to one of the preceding claims, characterized in that the position, the opening areas or the number of the individual chambers (18) of the Bodenrohelementsement (BR) associated access openings (24) of the connection opening (26) for supplying foam associated cover member (26). 19) depending on the distance of the respective access opening (24) to the connection opening (26) or of the volume of the respective chamber (18) is varied. Bodenrohelement according to claim 3 and one of claims 4 or 5, characterized in that in the vent opening (24) of the second cover member (20) a gas-permeable plug (27) sits. Bodenrohelement according to any one of the preceding claims, characterized in that the cover elements (19,20) are made of a plastic material. Bodenrohelement according to any one of the preceding claims, characterized in that the transverse webs (7,7a, 7b, 8) at its upper and lower cover layer (1,10) respectively associated upper and lower side with the upper and lower cover layer (1, 10) are glued. Bodenrohelement according to any one of the preceding claims, characterized in that at least one of the transverse webs (7,7a, 7b, 8) has a recess (7c, 8a) over which of the respective transverse web (7,7a, 7b, 8) from each other divided chambers (18) are interconnected. Floor element for a vehicle (S), such as a truck, semi-trailer (A) or trailer, characterized in that it is made of a Bodenrohelement (BR) formed according to one of claims 1 to 9 and that its chambers (18) with a foam filling (SF) are filled, which has passed into the chambers (18) via the longitudinal channel (21,22) of the formed as a hollow profile first cover member (19). Floor element according to claim 10, characterized in that the cover element (19) formed as a hollow profile, via which the foam is supplied, is substantially completely filled with foam. Method for producing a floor element for a vehicle (S), such as a lorry, semi-trailer (A) or trailer, comprising the following steps: Provision of a floor roughing element (BR) designed according to one of claims 1 to 9, Positioning the floor assembly (BR) such that the cover member (19) provided with the longitudinal channel (21, 22) is in a lower position than the opposite longitudinal side of the floor fitting (BR), - Filling the chambers (18) with a flowable foam, which is passed through the end opening (26) for supplying foam in the longitudinal channel (21,22) of the located in the lower position cover member (19), wherein the Bodenrohelement (BR ) supplied amount of foam is such that the foam in the expanded state, the chambers (18) of the Bodenrohelements (BR) completely fills, and - Expanding the chambers (18) supplied foam, wherein the foam during its expansion automatically in the chambers (18) rises until the chambers (18) are completely filled, wherein during the expansion of the foam contained in the chambers (18) Gases escape via at least one vent (24). A method according to claim 12, characterized in that the Bodenrohelement (BR) is positioned to be filled with the foam so that its chambers (18) are aligned substantially vertically. A method according to claim 12 or 13, characterized in that in the chambers (18) filled foam is a polyurethane foam. A method according to claim 14, characterized in that the foam has a density of at most 55 kg / m ³ .

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